One of your friends has shared a page with you.You can click the link above to view this page.

BrainGate Trial Shows Promise for Motor Impaired

Photonics.comJul 2006
PROVIDENCE, R.I., July 13, 2006 -- In a pilot trial of a device dubbed BrainGate, a man with paralysis of all four limbs could open simulated e-mail, play a game of Pong and adjust the volume on a TV using only his thoughts. The findings could offer hope to people with severe motor impairments, said John P. Donoghue, a professor of neuroscience at Brown University and director of its Brain Science Program. Donoghue led development of the system and was the senior author of a report on it being published in today’s issue of the journal Nature.

The article is the first to provide in-depth scientific findings from the trial of BrainGate, a brain-to-movement system created and tested by Cyberkinetics Neurotechnology Systems Inc. of Foxborough, Mass. Cyberkinetics, the forerunner of Cyberkinetics Neurotechnology Systems Inc., was founded in 2001 under a licensing agreement with the Brown University Research Foundation. Brown faculty and students created the company based on research and technology developed in Donoghue's lab.

John Donoghue, Brown University professor and director of its Brain Science Program. In early tests with a primate model, Donoghue and colleagues decoded brain signals that control limb and hand movements and demonstrated that a computer cursor, for example, could be controlled by thoughts alone. That model has worked successfully in human subjects. (Photo: Brown University)
BrainGate consists of a surgically implanted sensor that records the activity of dozens of brain cells simultaneously. The system also decodes these signals in real time to control a computer or other external devices. In the future, BrainGate could control wheelchairs or prosthetic limbs. The long-term goal: pairing BrainGate with a muscle stimulator system, which would allow people with paralysis to move their limbs again.

The first trial patient, a 25-year-old man with spinal cord injury, used the device for nine months of the 12-month study period. The team also discusses the initial performance of a second trial patient, a 55-year-old man with spinal cord injury.

Based on the experience of these patients, the team found that movement signals persist in the primary motor cortex, the area of the brain responsible for movement, long after a spinal cord injury; that spiking from many neurons -- the language of the brain -- can be recorded and routed outside the human brain and decoded into command signals; and that paralyzed humans can directly and successfully control external devices, such as a computer cursor and robotic limb, using these neural command signals.

"We found that cortical activity can be modulated voluntarily even years after spinal cord injury," said Leigh Hochberg, MD, a Brown alumnus and lead author of the article. "Some researchers might have predicted that this part of the brain would alter its function dramatically after the spinal cord was injured. But that doesn’t seem to be the case. The movement-related signals are still there.

"What’s truly exciting is this: The cortical activity of a person with spinal cord injury, controlling a device simply by intending to move his own hand, is similar to the brain activity seen during preclinical studies of monkeys actually using their hands," Hochberg said. "Whether it is real or attempted movement, neurons seem to respond with similar firing patterns."

Hochberg is an investigator in neuroscience at Brown and a neurologist at Massachusetts General Hospital, Spaulding Rehabilitation Hospital and Brigham and Women’s Hospital. He is also an instructor at Harvard Medical School and an associate investigator with the Rehabilitation Research and Development Service at the Providence VA Medical Center.

Donoghue, senior author of the article and chief scientific officer at Cyberkinetics, said technical problems arose during the pilot trial, including signal decline after months of recording. However, the patients’ control of the computer cursor and other devices was largely reliable. The first patient, for example, executed simple tasks such as moving a cursor to a target on a computer screen with 75 to 85 percent accuracy over many sessions. He also controlled a robotic arm, picking up pieces of hard candy and dropping them into a technician’s hand.

"What is also encouraging is the immediate response from the brain," Donoghue said. "When asked to 'think right' or 'think left,' patients were able to change their neural activity immediately. And their use of the device is seemingly easy. Patients can control the computer cursor and carry on a conversation at the same time, just as we can simultaneously talk and use our computers."

BrainGate is based on more than a decade of basic neuroscience research in the Donoghue lab, much of it funded by the National Institute of Neurological Disorders and Stroke, and much of it conducted by students. After proving the concept for BrainGate in experiments with monkeys, Donoghue and three Brown colleagues created Cyberkinetics to take their idea from bench to clinical trial.

Two of those founders -- Mijail Serruya, MD, a Brown Medical School graduate, and Gerhard Friehs, MD, a neurosurgery professor at Brown Medical School and director of functional neurosurgery at Rhode Island Hospital -- are co-authors of the Nature article. Jon Mukand, MD, clinical assistant professor of orthopaedics at Brown and principal investigator of one BrainGate trial site, also contributed. Maryam Saleh and Abraham Caplan, Cyberkinetics employees who worked directly with trial patients and are co-authors of the article, are Brown graduates.

At Brown, work on BrainGate continues through a collaboration with Cyberkinetics. Donoghue is working with Arto Nurmikko, professor of engineering, to develop a fully implantable, wireless microelectronic system to eliminate the need for external wires or bulky equipment. Michael Black, professor of computer science, is also working with the group to improve the neural decoding device so it can create control signals for complex motor tasks such as grasping.

Brown also has a collaborative research and licensing agreement with Cyberkinetics that allows eligible neuroscientists to access the company’s clinical trial data to conduct basic research.